DE2126678A1 - Deaggregation device for the production of dispersions with a high degree of dispersion - Google Patents

Description

DA-7478

description

to the
Patent application

the

Banyaszati Kutato Intezet, Budapest Hl / Hungary, Mikoviny and 2

concerning

Disassembly soldering device for the production of dispersions with a high degree of dispersion

(Priority: December 22, 1970 - Hungary - BA-2514)

The invention is a De saggregat soldering device with with significantly lower energy consumption and significantly continuously producing dispersions with a high degree of dispersity in a shorter period of time.

In many areas of industry, including the Canning industry, chemical reactions, the production of organophilic clay minerals, water purification Civil engineering, in the fine ceramic industry, enamel and Color induatry, in hydraulic binders, in building materials, In the case of foamed plastics, etc., the achievable or achieved degree of dispersion is of great importance, since

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while ensuring a corresponding degree of dispersion at Material consumption significant savings are possible and also the material quality can be greatly improved.

Various moistening, comminuting, grinding and mixing processes have previously been used to achieve the appropriate dispersion level, which have recently been replaced by processes that work with shear or impact, and these are then followed by the most suitable disaggregation process, which involves impact during the Shear works, replaced. The disaggregation by impact during shear is more successful and more modern than all previously known methods, but it is not widespread according to its value because - up to now no device could be produced that could have carried out the disaggregation processes in the appropriate quantity and quality over a long period of operation . The known disaggregation devices were mainly economical. the results are not satisfactory.

The known disaggregation devices do not allow recirculation, since in these the disaggregation process becomes discontinuous in the case of recirculation.

The recirculation is necessary because of the structure of the material to be disaggregated and dispersed can only be degraded gradually (e.g. with bentonite and similar materials) and because to achieve the corresponding shear effect a corresponding viscosity is required, which in many cases only through recirculation can be achieved.

The discontinuous recirculation technology of the known disaggregation devices harbors the danger that individual parts of the material go through the impact process more often, others less often? the received So the product will be inhomogeneous.

In the known disaggregation devices in generally a disc with a closely toothed crown and

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an also closely-toothed standing counter-disk is used, which engages between the teeth of the disk. In these daszu desaggregierende _r material to be dispersed from the inside flows out, in the outer Desaggregationsteil its velocity increases and the outer portion represents the material is a large space is available, therefore in the Desaggregationsvorrichtung a strong cavitation occurs. As a result of the cavitation, relatively few shear effects are exerted on the solid particles or on the liquid parts, and the energy requirement is also high.

Another disadvantage of the known disaggregation devices consists in the fact that in these the solid particles and the liquid parts in the radial direction flow and in the radially directed flow gaps as a result lose a large part of their energy due to the friction that occurs. The energy lost will reduce that for the amount of energy that can be used in shear.

Another flaw of the known disaggregation devices consists in the fact that the shear effect can only be changed by changing the number of revolutions « As a result of the cavtetion and the large frictional forces The energy consumption is very high, the devices are worn out relatively quickly and cannot continue be used.

The aim of the invention is to create a disaggregation device, which works continuously in the return flow, in which every part of the to be aggregated, to be dispersed in the return flow Materials practically rich number of impact -Shear processes in which the manufactured Dispersion has a high degree of dispersion and is completely homogeneous, in which there is no cavitation and strong frictional forces occur, the shear effect without changing the number of revolutions can be changed easily, quickly and continuously, which can be easily operated, even through lengthy periods Operating time works reliably, and if

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need less energy in a short time the disaggregation that Can carry out dispersion of a large amount of material

The disaggregation device according to the invention is lost the set goal by the fact that the shock-Schemng of the to disaggregating material to be dispersed an impeller and a disk with interlocking or side by side arranged ring gears is applied, the annular flow through cross-sectional areas of the flowing material filled space between the teeth, which are vertical to the direction of the material flow, on the whole with teeth occupied part of the device are practically the same size and that in the gear rings of the device between two adjacent teeth each limited to the circumference of the gear rim an oblique material flow si » chinging passage openings are, of which the openings in the ring gears of the impeller in the direction of the material flow with the direction of rotation of the circumference one Include obtuse angle.

Another characteristic of the invention is that that the surface against the ring gears of the impeller and / or the disc is conical or cylindrical is. ·

The invention is also characterized in that the impeller and / or the disc are mounted in such a way that that they are approaching or distant from each other can·

Another characteristic of the invention is that the opposite Tooth surfaces of the intermeshing gear rims are cylindrical · ■

Finally, a characteristic of the invention is that the opposing tooth surfaces of the intermeshing Ring gears are conical

The invention is illustrated with reference to the drawings Examples described where

Fig. 1 is a basic diagram of an embodiment of the disaggregation device according to the invention,

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Fig.2 the picture of the impeller of the one shown in Fig, I. Embodiment,,

Fig. 3 schematically in cross section a modified form of the embodiment shown in Fig. 1

Fig. 4 is another embodiment in which the to be disaggregated, to be dispersed material through the annular space along the circumference of the impeller and the Disk flows in the axial direction,

Fig. 5 shows a modified embodiment, which is similar to that in Fig. 4, with the difference that here several running wheels and discs alternate one behind the other are arranged. |

In the embodiment of the disaggregation device according to the invention According to Fig. 1, the impeller 1 is attached to the axis 2 and can thus be rotated at the same time. The axis 2 is in the bearing 4, which is on the housing part 3 of the device is designed, rotatably mounted »From the middle part of the disk 5 designed as Housing part with the housing part 3 of the device is assembled in any known way, a connection piece 6 protrudes for connecting the device to a pipeline, or to the introduction of the to be dispersed Material into the interior of the housing 3, 5 is used.The material that has flowed in is nozzle through the outlet 7 removed. f

On the surface of the impeller 1 opposite the Disc 5 are gear rims 8 formed from teeth. These ring gears lie radially from one another in such a way Distance that the toothed rims 9 formed from teeth protruding inward from the disk are pushed in between can be. The disk 5 moves together with the ring gears 9, so the ring gears rotate during operation 8 between the ring gears 9 in the direction of the arrow IO shown in Fig. 2.

Located between the teeth of the rotating ring gears 8 de an opening 11, which is oblique to the circumference of the

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Ring gear are formed. Their direction, viewed in the direction of the material flow, forms an obtuse angle with the circumferential direction of rotation. The side surfaces of these openings have a similar effect on the material, such as a rotating paddle wheel of a centrifugal pump, ie they can lift or convey the material to a certain height.

The material to be disaggregated, to be dispersed flows between the teeth of the gear rims 9 protruding from the disk 5 through similar openings 12. These However, openings can also deviate from the openings 11 of the ring gears 8 by the openings 12 in the direction the material flow viewed with the circumferential direction of rotation instead of an obtuse angle, include an acute angle.

This configuration of the openings 11, 12 of the ring gears 8 or 9 enables the further conveyance of the material flowing through in between, further safeguards for fluidic reasons that the material flowing through flows through the openings with low frictional forces, or the particles to be disaggregated have a strong impact be subjected. This type of flow is opposite the previously used radial flow is very advantageous.

In the embodiment shown schematically in Fig. 1, the wall of the housing part 3 is vertical to the axis 2, the tooth-side surface 13 of the impeller 1 has a something curved cross-section and the inner surface of the disc 5 is conical. The surface 13 and the inner surface of the disc 5, as well as that filled with the material to be dispersed Space between the ring gears 8 and 9 have such a shape and dimension that the direction of the material flow vertical annular cross-sectional areas starting from the connection piece are of the same size everywhere. That means that viewed radially outward from the axis line 14, each with a presented annular cross section

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~ * 7 -

the change in the radius - consequently the change in length of the Umf ans - by changing the width dimension of the annular Cross-section is balanced. As a result, the material flowing in through the connection supports 6 flows, spreading between the surface 13 and the disc 5, the way ^^ rass it in spite of increasing its speed the space between the surface 13 and the disk 5 completely fills, so no flow adversely affecting cavitation can occur.

The embodiment according to Fig. 3 differs from the embodiment according to Fig. 1 in that the surfaces of the teeth 8a protruding from the λ impeller 1 are not cylindrical but conical along the circumference of the gear rims. Similar surfaces delimit the peripheral surfaces of the toothed rims consisting of the teeth 9a, which protrude from the wall of the disk 5a. A further deviation is that the disc 5a can be moved in any known manner, e.g. with a screw connection 15, in the direction of the impeller 1 or away from it, i.e. the width of the gaps 16 between the side surfaces of the teeth of the gear rims 8a and 9a and thereby the shear effect without changing the number of revolutions of the impeller

I can be changed. _v

Flows in the shown in Fig. 4 embodiment, the inventive i Desaggregationsvorrichtung in the Anschlusstützen 6 flowed to be dispersed ma- * TERIAL only by the outer annular part of the impeller 17 and the stationary disk 18. In the case of the impeller 17 there is only a single ring gear, the teeth of which fill the entire width of the flow ring field. The openings 19 are just as high as the teeth that form them. The openings 19 enclose the same angle with the circumferential direction of rotation of the impeller 17 as the openings

II on the impeller 1 in the embodiment according to Fig ₀ 1 · The openings 21 between the teeth 20 of the stationary disk 18 are just as high as the openings 19. The Rich

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direction of the openings 21 is similar to the direction of the openings 12 in the version according to Fig. 1.

The design according to Fig. 5 is identical to the '.Vesen with the one according to Fig. 4, with the difference that several running wheels and stationary disks alternate here one behind the other are arranged. The width of the column between. the impellers 17 and stationary disks 18 - and thus also the shear effect - can also be made adjustable

The most important advantages of the disaggregation device according to the invention are the following:

It does not allow harmful cavitations to develop. Also the size of the flow occurring during the flow Frictional forces are reduced, which is achieved by the inventive Formation of the openings or gaps is secured. As a result - according to the measurements Energy requirements for disaggregation, dispersion or Shear only 27-29% of the energy requirements of the known devices.

As a result of the elimination of cavitation, the shear effect increases significantly and colloidal dispersions can occur such materials are produced that do not correspond to the previously known devices Fineness dispersed, or could be transformed into coarse-grained dispersions.

Another advantage is that as a result of the ■ ^; pump-like design of the impeller and the disc, the device - in addition to reducing the energy consumption and a greater shear effect - also works as a pump and can convey the colloidal dispersion under a pressure of several atmospheres.

The shear effect can be continuously regulated by the fact that the impeller and the disc or several of them Pairs in the axial direction can be shifted opposite one another. The number of impellers and discs Pairs can meet the given technological requirements

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to be chosen according to. The installation of the pairs one behind the other can be carried out quickly with a relatively small assembly belt. In addition to disaggregation, Dispersion tasks also for the pre-shredding of coarse-grained Materials are used «

The invention is not limited to the embodiment of the components of the deaggregation devices explained by way of example. If these are replaced by components: with a similar function and a similar effect but with a different configuration, the scope of protection of the invention is not replaced. Thus, for example, the impeller and the disc d are also formed in the manner that both eg opposing rotierent the continuous matching of the flow cross-sections with the flow rate can be applied to anäeie ^ ^ fIfSe SÄMigeführt,

the size of the angle of the flow openings with the circumferential direction of rotation can depend on the quality, The viscosity of the material flowing through is selected and accordingly for the impeller-disc pairs lying one behind the other can be changed according to the given technological requirements, etc.

Claims

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Claims (1)

- ίο - Pat corresponds to objections ll De a aggregat ioiisvorrichtung for the production of dispersions with a high degree of dispersion, in which the 8toss-. ^{For the} material to be disaggregated, dia- and pergated, an impeller designed with interlocking or juxtaposed toothed rims and a disk is used, which means that the ring-shaped flow-through surfaces are vertical to the direction of the material flow of the flowing material between the teeth / 8, 8a, 9, ^% 9a, 20 / are practically the same size over the entire part of the device filled with teeth and that in the tooth rings of the device between two adjacent teeth / 6, 8a , 9, / 9a, 20 / are delimited by these openings / 11, 12, 19, 21 / which ensure an inclined Haterialntröriung, of which the openings / 11, 12, 19 »21 / in the gear rims of the impeller / II, 19 / when viewed in the direction of the material flow, include an obtuse angle with the circumferential direction of rotation. W 2. Device according to claim 1, characterized ge characterizing ze ichne t, that directed to the sprockets surface dea impeller / 17 /, and the S _c Heibe / 18 / is cylindrical. 3. Apparatus according to claim 1 or 2, characterized in that the opposing Tooth surfaces of the interlocking gear rims are designed as conical oaks. 4. Device according to -.Anspruch 1, thereby g e k e η η ζ e that rejects the in the direction of the flow is the last ring gear on the impeller / 17 /. 209829/0829 Blank page